KR101389039B1 - Actuator for Miniature Opitcal Lens - Google Patents

Abstract

The present invention relates to a small optical lens driving apparatus, and more particularly, to a small optical lens driving apparatus which includes a driving unit and a magnetic circuit for driving the driving unit. A spring for generating a restoring force when the driving unit is driven; A housing for coupling said components; Since the magnetic body is magnetized by the permanent magnet so that the components can be fixed and can serve as a contact point, it is not necessary to use a separate component that can make contact, so that the product can be miniaturized, The present invention provides a small optical lens driving apparatus capable of reducing the manufacturing time and manufacturing cost according to the shortening of the number of process steps, and in particular, by using the steel ring, the manufacturing cost can be reduced by using the rectangular permanent magnet while improving the driving force.

Auto focus, optical lens, actuator

Description

[0001] The present invention relates to a small optical lens driving apparatus,

The present invention relates to a small optical lens driving apparatus, and more particularly, to a small optical lens driving apparatus which includes a driving unit, a yoke formed of a magnetic body capable of serving as a contact point in addition to fixing the spring unit, the magnetic circuit unit, By reducing the number of components, the product can be miniaturized, manufacturing time and manufacturing cost can be reduced according to the shortening of the number of process steps, and a steel ring reacting with the magnetic body magnetized by the permanent magnet is formed in the driving unit, And it is also possible to improve the response speed of the focus after driving of the driving unit by maintaining the linearity of the driving curve of the driving unit at the same time as the driving of the driving unit, and to adopt the rectangular permanent magnet to reduce the unit price.

A digital camera capable of automatically focusing an image focus needs a driving device capable of varying the position of a lens. In general, an optical lens driving device used in a digital camera converts a rotational motion of a stepping motor or a DC motor into a conversion device A method of linearly moving the focus lens in the direction of the optical axis is widely used.

However, it is difficult to mount a rotary motor and a gear box in a driving device of a small optical lens used in a limited space such as a camera module of a mobile phone, and a linear DC motor (LDM ) Are used.

In addition, in the method of a linear DC motor used in a small optical lens driving device, both a coil moving linear DC motor and a magnet moving linear type DCM are used. However, The permanent magnets are heavier and the weight of the moving part increases, so that the coil moving type as shown in Figs. 1 and 2 is preferred.

1 and 2, the conventional miniature optical lens driving apparatus 180 includes a driving unit 110 including a lens holder 112 having a lens assembly 111 coupled with a fastening method of screws, A magnetic circuit unit 130 composed of upper and lower permanent magnets 131 and 132 and a coil 133 is formed so as to drive the driving unit 110 by using a magnetic force and the driving unit 110 is driven by the magnetic circuit unit 130 The upper and lower housings 141 and 142 constitute a spring part 120 composed of upper and lower springs 121 and 122 so as to form a restoring force when driving. 142, and a central housing 143. The housing 140 includes a housing 140,

A magnetic body 144 is formed between the upper housing 141 and the central housing 143 to increase the driving force of the driving unit 110 by multiplying the magnetic force.

The linear motion of the conventional small optical lens driving apparatus 180 as described above is performed by applying a current to the coil 133 and performing a linear motion using the optical axis direction magnetic force (Fleming's left-hand rule) generated when the current is bridged with the magnetic flux do.

However, the conventional miniature optical lens driving apparatus 180 having the above-described structure is not shown in the drawing for the purpose of processing the external magnetic force when it is mounted on a communication device, The problem of increasing the overall size of the product has been raised.

Further, since the upper and lower housings 141 and 142 and the central housing 143 for fixing the respective components are formed, the number of parts increases, Was exposed.

In addition, since the driving unit 110 is driven using only the magnetic force of the permanent magnet 131 and the coil 132 of the magnetic circuit unit 130, the driving force is weak.

In addition, the magnetic force is proportional to the product of the intensity of the magnetic flux density and the amount of the coil current, as can be seen from Lorentz's law. The conventional miniature optical lens driving apparatus 180 is applied to the coil or the steel ring Since the magnetic flux density decreases as the distance from the permanent magnet increases, a nonlinear characteristic occurs between the current and the drive displacement. Therefore, when the lens (not shown) mounted on the driving unit 110 attempts to focus after driving the driving unit 110, there occurs a problem that the focusing reaction speed is slowed down.

In addition, when the permanent magnets are manufactured, the problem of increasing the unit price is exposed by machining into a circular shape.

In order to solve the above problems, a small optical lens driving apparatus of the present invention includes a driving unit including a lens holder coupled to a lens assembly, a spring unit formed on a driving unit to restore the driving unit to an initial position, And a housing for coupling the components together. The small optical lens driving apparatus according to claim 1, wherein the first coupling portion is formed on the lower housing, And a second coupling portion corresponding to the first coupling portion of the lower housing, wherein the driving portion and the spring portion, the magnetic circuit portion, and the housing are formed so as to cover the component, To further form a magnetic body magnetized by the permanent magnet And a gong.

The driving power of the driving unit is increased in response to the magnetic body magnetized by the permanent magnet on the upper side of the lens holder formed in the driving unit of the small optical lens driving apparatus of the present invention and the driving unit is further formed with a steel ring .

The permanent magnets of the small optical lens driving apparatus of the present invention are characterized by using divided magnets having a rectangular shape.

The small optical lens driving apparatus of the present invention includes a driving unit, a yoke formed of a magnetic body capable of serving as a contact point and a role of fixing the spring unit, the magnetic circuit unit, the upper and lower housings, It is possible to reduce the manufacturing time and manufacturing cost due to the shortening of the process number.

Further, a steel ring, which reacts with a magnetic body magnetized by the permanent magnet, is formed in the driving unit to increase the driving force of the driving unit and maintain the linearity of the driving curve of the driving unit, thereby improving the response speed of the driving unit after the driving unit.

In addition, it is a useful invention which can reduce the unit cost by adopting a rectangular permanent magnet.

Hereinafter, the structure of the present invention will be described in detail with reference to the accompanying drawings.

3 to 4, the present invention includes a driving unit 10 for mounting and driving a lens, a spring unit 20 for generating a restoring force when the driving unit 10 is driven, A housing 40 to which the driving unit 10, the spring unit 20, and the magnetic circuit unit 30 can be coupled, and a magnetic circuit unit 30 for driving the driving unit 10, the spring unit 20, And the formed magnetic body 50.

First, the driving unit 10 includes a lens assembly (not shown) and a lens holder (not shown) that is coupled to the lens assembly by screwing, and mounts a lens therein.

The spring portion 20 is composed of an upper spring 21 disposed on the upper side of the driving portion 10 and a lower spring 22 disposed on the lower side of the driving portion 10. [

The magnetic circuit unit 30 for driving the driving unit 10 is coupled to a side surface of the driving unit 10 and forms a coil 32 to be supplied with power, And a permanent magnet 31.

The permanent magnet 31 may be formed in various shapes, but it may be formed in a shape divided on a quadrangle so as to reduce the manufacturing cost.
The housing 40 includes an upper housing 41 and a lower housing 42 so that the driving unit 10, the spring unit 20, and the magnetic circuit unit 30 can be coupled to each other.
The magnetic body 50 is formed outside the permanent magnet 31 so that the magnetic body 50 can be magnetized by the permanent magnet 31 of the magnetic circuit unit 30. The magnetic body 50 includes the driving unit 10, , The magnetic circuit portion 30, and the housing 40).
A first engaging portion (not shown) is formed at one side of the lower housing 42 of the housing 40 and a second engaging portion (not shown) is formed at one side of the magnetic body 50 at a point corresponding to the first engaging portion (Not shown), so that the magnetic body 50 and the housing 40 can be fixedly coupled to each other, and the first and second coupling portions (not shown) Can be formed in various shapes, but it is preferable to use a hook-type joining method comprising an arm and a water which are easy to be joined and separated.

The magnetic body 50 is fixed to the driving unit 10, the spring unit 20, the magnetic circuit unit 30, and the housing (not shown) by being fastened to the first and second engaging parts (40) and serves as a contact point.

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Further, a steel ring 60 may be further formed on the upper side of the driving unit 10 to improve the driving force of the driving unit 10.

The steel ring 60 is configured to react with the magnetic body 50 magnetized by the permanent magnet 31 to form a magnetic force so as to increase the driving force of the driving unit 10. In particular, The driving unit 10 can maintain linearity when the driving unit 10 is driven by the permanent magnet 31 and the coil 32 of the driving unit 10.

Hereinafter, the operation of the small optical lens driving apparatus of the present invention will be described.

First, each component of the small optical lens driving apparatus 80 is assembled.

Here, in order to reduce the size and weight of the assembly method of the present invention, the bonding between the respective components is combined using an adhesive, which is a generally known assembly method, and a detailed description thereof will be omitted.

The compact optical lens driving apparatus 80 of the present invention having completed the assembling as described above applies power to the coil 32 of the magnetic circuit unit 30 so that the permanent magnet 31 and the coil 32 of the magnetic circuit unit 30 The driving unit 10 is linearly moved by the generated magnetic force.

The magnetic force generated by the coil 32 when the magnetic flux formed by the permanent magnet 31 and the current flowing through the coil 32 are connected to each other by the magnetic circuit 30 The driving unit 10 coupled to the coil 32 forms a driving force that can be driven.

When the amount of current flowing in the coil 32 of the magnetic circuit 30 is gradually increased by the above-described principle, the magnetic force generated in the coil 32 increases in proportion to the amount of current increase. At this time, The driving unit 10 moves when the magnetic force applied to the spring unit 20 exceeds the initial elastic force of the upper and lower springs 21 and 22 of the spring unit 20. [

In addition, the elastic force of the spring portion 20 increases in accordance with the amount of movement of the driving portion 10 to a magnitude of the same force in a direction that conflicts with the magnetic force.

That is, if the relationship between the magnetic force and the elastic force of the same magnitude is utilized while the directions of the forces are in conflict with each other, the amount of current input to the coil 56 of the magnetic circuit unit 30 is adjusted and controlled, It is possible to control the lens movement amount of the lens 80.

When the displacement of the lens is controlled by the amount of current flowing through the coil 32 of the magnetic circuit unit 30 and then the current is removed, the driving unit 10 applies the elastic force of the upper and lower springs 21 and 22 of the spring unit 20 To the initial position.

On the other hand, in the magnetic body 50, the magnetic force of the permanent magnet 31 is induced to increase the magnetic force generated by the permanent magnet 31 of the magnetic circuit unit 30 and the coil 32 to which the current is applied, (10).

Since the magnetic body 50 in contact with the permanent magnet 31 of the magnetic circuit unit 30 is in a magnetized state, the distance between the steel ring 60 formed on the upper side of the driving unit 10 and the upper side of the magnetic body 50 A magnetic force is generated, and the driving force of the driving unit 10 can be further improved.

The intensity of the magnetic force is determined by the magnitude of the magnetic flux density applied to the coil 32 and the steel ring 60. Since the magnetic flux density applied to the driving unit 10 during driving is not uniform, Since the driving unit 10 can not be linearly driven due to the development, there is a problem in that the speed of focusing operation for focusing is slow after the driving is completed.

In order to solve such a problem, in the present invention, by driving the driving unit 10 using the magnetic force between the steel ring 60 and the magnetic body 50, the linearity can be maintained.

1 is a perspective view showing a conventional compact optical lens driving apparatus.

2 is a sectional view of the small optical lens driving apparatus shown in Fig.

3 is a perspective view showing a small optical lens driving apparatus according to the present invention.

4 is a sectional view of the small optical lens driving apparatus shown in Fig.

◈ Explanation of codes for main parts of drawing ◈

10: driving part 11: lens assembly

12: lens holder 20: spring portion

21: upper spring 22: lower spring

30: magnetic circuit part 31: permanent magnet

32: coil 40: housing

41: upper housing 41a: first coupling portion

42: lower housing 50: magnetic body

51: second engaging portion 60: steel ring

80: Small optical lens driving device

Claims (3)

A spring portion formed on a driving portion for restoring the driving portion to an initial position, a permanent magnet for generating a magnetic flux at all times, and a coil for moving the driving portion by a magnetic force generated in the lens portion. And a housing for coupling the drive unit, the spring unit, and the magnetic circuit unit together, the small optical lens drive unit comprising: The housing may be provided as an upper housing and a lower housing so as to engage the driving unit, the spring unit, and the magnetic circuit unit, Wherein the permanent magnet is formed in a shape that can cover the driving unit, the spring unit, the magnetic circuit unit, and the housing, and further, the magnetic body is magnetized by the permanent magnet. [2] The apparatus of claim 1, further comprising a steel ring on the upper side of the lens holder of the driving unit to increase the driving force of the driving unit in response to the magnetic body magnetized by the permanent magnet and to maintain the linearity of the driving unit, A small optical lens driving device. The small optical lens driving apparatus according to claim 1, characterized in that the permanent magnet uses a divided magnet having a rectangular shape.

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